RU180496U1 - Device for monitoring the tightness of inflatable chambers of the seed of the continuous casting machine - Google Patents

Abstract

The utility model can be used as a means of monitoring the tightness of inflatable seed chambers. The task is to provide continuous monitoring of the tightness of the inflatable seed chambers after being introduced into the mold until the start of metal casting. The problem is solved by the fact that a device is proposed for monitoring the tightness of inflatable seed chamber chambers for continuous casting machines, including a pressure sensor 1 installed in the air supply manifold 2, located in the housing of the seed 3, with the measuring wires 4 brought out, an intermediate terminal block 6, a conversion block 7, a block visualization 8 and a connecting wire 5, one end of which is connected to the measuring wires 4 of the pressure sensor 1, and the second end to the input of the intermediate terminal block 6, both connections are quick disconnect, the output of the intermediate terminal block 6 is connected to the input of the conversion unit 7, the output of which is connected to the input of the visualization unit 8.

Description

The utility model relates to the field of metallurgy, in particular to the continuous casting of steel on continuous casting machines using seed with sliding links and can be used as a means of monitoring the tightness of inflatable seed chambers.

Control gauges are known for checking the tightness of inflatable seed chambers before putting it into a mold (Fundamentals of Steel Production [Electronic resource]: a manual for colleges, lyceums and technical schools / KN Vdovin, Yu. A. Kolesnikov. - Magnitogorsk: MSTU, 2011, p. 182-183).

A disadvantage of the known device is the lack of control of air pressure in the inflatable chambers of the seed after introducing it into the mold until the metal is fed into the mold.

Other devices that provide control of air pressure in the inflatable chambers of the seed after its introduction into the mold, in known sources was not found.

The problem solved by the claimed utility model is to increase the reliability of metal casting at the continuous casting machine at the initial stage and reduce the cost of eliminating the consequences of accidents that occur when the seed is torn off (shifted) after the metal is fed into the mold.

The technical result is to provide continuous monitoring of the tightness of the inflatable seed chambers after its introduction into the mold until the start of metal casting.

To solve the problem and achieve a technical result, a device is proposed for monitoring the tightness of inflatable seed chamber chambers at a continuous casting machine, including a pressure sensor installed in the air supply manifold located in the housing of the seed with test leads brought out, an intermediate terminal block, a conversion block, a visualization block and a connecting a wire, one end of which is connected to the measuring wires of the pressure sensor, and the second end to the input of the intermediate terminal block, both of which eniya made quick, the intermediate output terminal unit connected to the input conversion unit, which output is connected to the input imaging unit.

The essence of the claimed utility model is illustrated in the drawings, where:

- figure 1 schematically shows the design of the claimed device in two positions, and - the preliminary position of the seed for its "inflation", 6 - the initial position of the seed for casting metal;

- figure 2 schematically shows the design of the seed with sliding links with a pressure sensor installed in the collector;

- figure 3 shows the structural diagram of a system for measuring pressure in the seed, implemented at CCM 1-4 KKC OJSC "MMK";

- figure 4 shows the timing diagram of the change in the pressure signal in the seed, obtained using a pressure measuring system in the seed, implemented on CCM 1-4 CCC OJSC "MMK", for the case of establishment of the seed with leaky cameras.

The tightness control device of the inflatable seed chamber chambers includes a pressure sensor 1 with a unified output signal installed in the air supply manifold 2, located in the seed housing 3, with the test leads 4 outward. The test leads 4 of the pressure sensor 1 are connected to the intermediate terminal block by means of a connecting wire 5 6. Connections of the wire 5 to the measuring wires 4 and the intermediate terminal block 6 are quick disconnect. The intermediate terminal block 6 is a terminal connection housed in a protective metal housing. The output of the intermediate terminal block 6 is connected to the input of the conversion unit 7. The conversion unit includes a power supply for pressure sensor 1 and a remote sensor signal input module with the ability to transmit information via a standard digital interface, for example, Ethernet. The output of the conversion unit 7 is connected to the input of the visualization unit 8. The visualization unit 8 can be implemented either as a separate workstation or as part of an existing automated control system for continuous casting machines.

The claimed device operates as follows.

After setting the seed in the preliminary position, the connecting wire 5 is connected to the measuring wires 4 of the pressure sensor 1. In this case, the second free end of the connecting wire 5 is connected to the intermediate terminal block 6 mounted on the casting site in a place protected from metal splashes. Then, the inflatable seed chambers are inflated to the required value and, using the electric drive of the SCB rollers, they are moved to the initial position to start the metal casting process. In the process of moving the seed from the preliminary position to the initial position, the process staff constantly monitors the integrity of the connecting wire portion 5 located between the seed head and the end wall of the mold. The unified signal from the pressure sensor 1 through the connecting wire 5 through the intermediate cross-block 6 enters the conversion unit 7, installed in the automation room CCM. The conversion unit provides power to the pressure sensor, the conversion of the measured signal and the transmission of information about the pressure in the seed to the visualization unit 8 installed at the operator’s CCM position. The pressure measurement in the seed is carried out continuously up to the moment of the start of metal casting. When the metal is fed into the mold, the connecting wire 5 burns out and the pressure measurement stops.

To justify the advantages of the utility model, the inventive installation was introduced at four-strand continuous casting machines 1-4 CCC of OJSC MMK. As pressure sensors 1, an overpressure sensor DI415 manufactured by Piezoelectric LLC with a unified output signal of 4-20 mA was used. The BPD-2 dual terminals are installed on the seed housing and intermediate terminal block 6 to provide a quick-disconnect connection for the connecting wires 5. As the connecting wire 5, a flat cable ШВВП-2-1,5 is used, crimped on both sides with cable lugs for connecting to the terminals BPD-2. Connecting wires 5 burn down at every start of the continuous casting machine, so a new set of wires is required for each start of the continuous casting machine. The signals from the sensors through the intermediate terminal block 6, installed at the station of the continuous casting machine caster, are transmitted to the conversion unit 7. The conversion unit 7 supplies power to the pressure sensors 1 with a DC voltage of 24 V. The conversion unit 7 also includes a universal signal input module ADAM 6017 manufactured by Advantech, which carries out discretization of pressure sensor signals and transmits over Ethernet data on the current value of the pressure in the seed chambers to visualization workstation 8 and the control system server CCM. Information about the current value of the pressure in the seeds is displayed on the monitor at the operator's post and stored in the database of the automated control system of continuous casting machines. An example of the use of the seed pressure measurement system at the CCM 1-4 CCC is shown in Fig. 4, where t ₁ is the moment of inflating the seed chambers and its establishment to its original position to start casting metal; t ₂ - uncontrolled decrease in pressure in the seed chambers; t ₃ is an attempt to re-inflate the seed chambers; t ₄ - repeated pressure reduction in the seed chambers; t ₅ - inflation of the backup seed chambers and its establishment in the initial position to start casting metal; t ₆ - the beginning of the casting of metal.

Using the utility model will provide continuous monitoring of the tightness of the inflatable seed chambers from the moment it is introduced into the mold until the start of metal casting, which will increase the reliability of metal casting at the continuous casting machine at the initial stage and reduce the cost of eliminating the consequences of accidents that occur when the seed is separated after the metal is fed into the mold.

Claims (1)

A device for monitoring the tightness of the inflatable chambers of the seed of a continuous casting machine having an air supply manifold located in the seed housing, comprising a pressure sensor with measuring wires brought out, adapted to be installed in the air supply manifold, an intermediate terminal block, a conversion unit, a visualization unit, and a connecting wire, one end of which is connected to the measuring wires of the pressure sensor, and the second end to the input of the intermediate terminal block, and ba connections are quick, with an intermediate output terminal unit connected to the input conversion unit, which output is connected to the input imaging unit.

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